(Phys.org) —A trio of researchers at Tohoku University in Japan, led by Masahiro Hotta, has proposed a new way to teleport energy that allows for doing so over long distances. In their paper published in Physical Review A, the team describes a theory they've developed that takes advantage of the properties of squeezed light or vacuum states to allow for "teleporting" information about an energy state, allowing for making use of that energy—in essence, teleporting energy over long distances.

AbstractQuantum energy teleportation (QET) is, from the operational viewpoint of distant protocol users, energy transportation via local operations and classical communication. QET has various links to fundamental research fields including black-hole physics, the quantum theory of Maxwell's demon, and quantum entanglement in condensed-matter physics. However, the energy that has been extracted using a previous QET protocol is limited by the distance between two protocol users; the upper bound of the energy being inversely proportional to the distance. In this paper, we prove that introducing squeezed vacuum states with local vacuum regions between the two protocol users overcomes this limitation, allowing energy teleportation over practical distances.

The greatest mystery associated with LENR and the hardest question to answer is how nuclear energy production can occur without gamma ray emissions and unstable isotope production. This most puzzling behavior of the LENR reaction could well be explained by a newly discovered but experimentally verified Quantum mechanical protocol called Quantum Energy Teleportation(QET)

QET is a process where energy is transferred between to particles through the vacuum using quantum entanglement in a many bodied system.

QET requires two conditions to hold; first the sender of the energy and the receiver of the energy must be entangled with each other, second, the energy must be produced by the sender and received by the receiver.

First, we will talk about how high energy entanglement happens. Quantum Mechanics(QM) is impervious to common sense. The most counter intuitive principle that confuses us is how a very hot and energetic environment can exist in a state of coherence, entanglement, and Bose condensation.

But first, let us understand how the vacuum works.

This perception is universal among all of us; we think that only gases cooled to temperatures near absolute zero can be coherent and entangled. So how can such an uniform and stable environment be produced at the roiling and searing temperatures that vaporize metal.

Such an unexpected condition is a direct result of the prime rules in QM, the Heisenberg Uncertainty Principal (HUP). The HUP is a fundamental theory in quantum mechanics that defines why a scientist cannot measure multiple quantum variables simultaneously. This rule states that the energy of a particle and its position are tied together.

Quantum uncertainty has real effects on things. Early on, Heisenberg offered an observer effect at the quantum level as a physical explanation of quantum uncertainty. As time rolled on, it became clear that the uncertainty principle is inherent in the properties of all wave-like systems, and that it arises in quantum mechanics simply due to the combined matter wave nature of all quantum objects; In other words, that is everything in our world. The uncertainty principle actually defines a fundamental property of quantum systems. It is a physical explanation of reality and is not a statement about the observational success of current technology. In order to understand LENR, we must look on the subatomic world as waves and waves have a long reach that can extend a long way.

First, let us talk about the vacuum and how the excitation of the vacuum changes the nature of the vacuum. See the section of the reference starting on page 12 at the bottom of page 12 until we get to the end of section two.

The HUP is real in its nature. This protocol actually defines what happens to a particle as a result of energy added to the vacuum. Usually, when the particle is restricted to a small space, its energy goes up. Think of a particle as a tiger. When given a wide plain to relax in, it finds a tree to lay under where it stays put. But is that tiger is put in a small cage, the nervous animal paces back and forth trying to find a way out. But the converse is also true. Strange enough, when the energy of the vacuum that houses the pair of particles goes up, the position of the two particles will come together and they become one particle.

When the vacuum that encloses two or more particles becomes saturated with EMF energy, these particles share their waveforms through the 5th dimension with out the 4 dimensional world knowing anything about it so that the particles become entangled and equal in energy. Yes, there is a 5th dimension in theoretical physics.

If a spark is discharged, the vacuum in the vicinity of the spark becomes excited because energy from the spark goes into the vacuum. The vacuum wants to maintain a zero energy level, so the vacuum reduces the energy of another part of the vacuum below the zero enrgy point. This state of affairs is called negative energy. The scientific condition is called a squeezed vacuum.

Think of the vacuum as a lake with waves on its surface. If a meteor comes down and inparts a large amount of energy to that lake, the waves, the water, and the fish will all disappear. The surface of the lake will be squeezed by the energy of excitation that the meteor has imparted into it and the fluctuation in the background energy of the lake will go away. The lake can no longer impart energy fluctuations to any particles that were floating on the surface of the lake. Any particles on the lake’s surface cannot change their nature by the absorption of random fluctuations.

All these particles will remain entangled with each other until the water comes back into the lake bed. They will combine into one super particle no matter where they were located physically on the surface of the lake before the meteor hit.

Saying this in another way, if two or more particles are enclosed in a strong enough magnetic field, they will share energy and become entangled because the vacuum is saturated with energy. These multiple particles become essentially one particle while the vacuum is saturated.

The energetic vacuum suppresses quantum fluctuations and decoherence is disabled. The system becomes entangled with total energy sharing; see:

Because the soliton (BoB) is composed of many Surface plasmon polaritons (SPPs), the energy that is produced by the collection of particles at the other end of the magnetic beam (Alice) even if the Alice particles are separated far apart from each other, the Alice particles will be teleported together and the energy of their fusion will be shared equally among all the individual entangled and coherent SPPs inside the soliton.